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The synthetic route to 1-(2-pyridyl)-2-naphthols via plex polycyclic compounds was clouded by the howl- the three-step process outlined in Scheme I ha...
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OVERCROWDED MOLECULES.I1

J. Ory. Chem., Vol. 36,No. 20, 1971 2991

Overcrowded Molecules.

11. 4,5-Bis(2-pyridyl)phenanthrene-3,6-diols

D. L. FIELDS" AND T. H. REGAN Research Laboratories, Eastman Kodak Company, Rochester, New York 14660 Received January 6 , 1971 The ketene acetal adducts of several azoniaanthracene, axoniabensanthracene, and diazoniapentaphene salts were used to prepare (2-pyridy1)naphthols 5, (2-pyridy1)phenanthrols 7 and 9, and bis(2-pyridyliphenanthrenediols 11, 13, and 15, respectively, by a modification of a known procedure. The phenanthrene-3,6-diols having pyridine substituents at the 4,5 positions (11)show a high degree of steric strain which strongly influences their uv, mass, and nmr spectra.

The synthetic route to 1-(2-pyridyl)-2-naphtholsvia the three-step process outlined in Scheme I has SCHEME I

I

2

-

1

plex polycyclic compounds was clouded by the h o w l edge that ketones 2, generated from ketal precursors by acid treatment, are themselves acid labile, readily degrading t o a mixture of 4 and 5 , with 4 often pred~minating.~ Accordingly, the success of this synthesis was thought to depend on the isolation of these rather elusive intermediate ketones in useful yields. Fortunately, however, the hydrolytic cleavage product 4 readily reverts to 2 in high yield on treatment with acetic anhydridesodium acetate a t room temperature. More importantly, this reagent at reflux temperature converts 4, via 2, to the desired product 3, exclusively. Thus the initial hydrolysis of ketal 1 may be carried out in refluxing 6 N HCl without concern for the nature of the products, be they 2, 4, or 5, since treatment of the resulting mixture with acetic anhydride-sodium acetate at reflux temperature will convert each of them to the same final product, 3.5 Application of this modified synthesis (eq 1) to the previously described azoniapolycyclic ketene acetal Ha0 +

1

AozO-NaOAc

+ [2 and/or 4 + 51 +3+5 A A

Ha0

+

(1)

3

been utilized for the preparation of two new classes of molecules with exceedingly high steric strain. One set, the S-te~t-butyl-l-(2-pyridyl)naphthalenes, has already been described.' In this paper, some further observations on the synthetic pathway are noted, and the synthesis and basic spectral properties of the second class of sterically hindered compounds, the 4,5-bis(2-pyridyl)phenanthrene-3,6-diols, are described. An X-ray crystallographic structure determination of one of these compounds was undertaken by Smith and is discussed elsewhere. The pyridine rings in these nonplanar, and therefore chiral, phenanthrenes have a spatial relationship similar t o that of the phenyl groups in [ 2 . 2 ] metacyclophanes, being almost coplanar and held in face-to-face proximity. The combination of severe ring strain and unusual geometry has pronounced effects on their physical and chemical properties, some aspects of which are reported here; certain others are under current investigation. Results and Discussion Synthesis.--Prior to this study, our envisioned adaptation of Scheme I to the synthesis of more com(1) D. L. Fields and T. H. Regan, J . Org. Chem.. 36,2986 (1971). (2) D. L. Smith and E. X. Barrett, Acta CrystaZZogr., Sect. B , 27, 419 ( 197 1). (3) C . J. Brown. J . Chem. Soc., 3278 (1953).

adductsa shown in Scheme I1 has provided the indicated naphthols and phenanthrols in 85-90% yields. I n like manner, bis adducts loa-e, 12, and 14 (Scheme 111), obtained from stereo~elective~ cycloadditions of ketene diethyl acetals to 4a,Sa-, 4a,12a-, and 12ajl4a-diazoniapentaphene salts, were converted without difficulty to the desired phenanthrenediols lla-e, 13, and 15, respectively. The structural assignments of the new products were supported by elemental analyses (4) (a) D. L. Fields and T. H. Regan, J . Org. Chem., S6, 1870 (1970). (b) For example, 1 (Ri, Rz = H ; X - = ClOn-) gives on treatment with 6 N hydrochloric acid a t 90" for 0.5 hr a mixture of 4 (84%) and 6 (9%); no 2 could be isolated.

PI H

H

4

5

( 5 ) A minor limitation t o this procedure exists when 4 possesses a 5-

hydroxyl substituent, in that 0-acylation-elimination leading t o a coumarin by-product competes favorably with the desired C-acylation-elimination. (6) D. L. Fields, T. H. Regan, and J. C. Dignan, J . Org. Chem., 98, 390 (1968). (7) Adducts loa-e, 12, and 14 each are believed t o be a mixture of geometric isomers formed from bis cycloadditions in which the ketene acetal had added both t o the same side and from opposite sides of the diazoniapentaphene ring (see ref 6) in a stereoselective or, when Rz = H, a stereospecific manner. This is inconsequential in the preparation of l l , l S , and 16.

2992

J. Org. Chem., Vol. $6, No. 90, 1971

FIELDS AND REGAN

of l l b along the twofold symmetry axis.

Figure 1.-View

SCHEME I1 Et0

&

OEt

& 1

of I l b normal to one of the pyridyl rings.

00 R

SCHEME I11

5

c10,-

OEt

Figure 2.-Projection

0

-

8:Q& 6

00 8 a, R =

00

-

9

H b,R = CH,;c, R C,H,; d, R=Br

(Table I11 and IV, Experimental Section) and by the usual spectral means, selected results of which will be discussed in the following sections. Molecular Structure of 11b.-The compounds of prime interest are, of course, the 4,5-dipyridyl derivatives lla-e, products which if completely planar and free of angle and bond deformations would have the two pyridyl rings occupying the same space. Obviously considerable altering of normal bond angles and lengths is necefsary for 11 to have even the minimum-allowed -3-A separation between their pyridine ringsea The nature and extent of the deviations have been clarified through a single-crystal X-ray analysis of a representative member, l l b . Although the details of this structure determination are being reported elsewhere,2 a brief qualitative description of the results is warranted here. I n agreement with conclusions drawn from nmr data that will be commented on later, each pyridine of l l b is found to be intramolecularly hydrogen bonded to the neighboring hydroxyl group, creating a twofold axis of (8) When aromatic rings are held face t o face and are not constrained, they have a normal “van der Waal” separation of -3.4 1;see J. M . Robertmon, “Organic Crystals and Molecules.” Cornel1 University Press, Ithaoa, N. Y., 1853, pp 157,174,206,270.

- 13

12

OEt OEt

15 14 a, R,, RZ = H ; b, R, = H , R, = Br; c, 11, = H, Itz = CH,; d, R, = CH,, RZ = H; e, R1 = CH,, R, = CH,

symmetry. As can be inferred from Figure 1, the distortion is distributed over the entire framework of the molecule in such a way that the trigonal symmetry of the bonds around any particular carbon bond is not greatly disturbed. X o major segment of the molecule is truly planar; yet all individual rings are approximately planar. The pyridyl rings have a stair-step relationship to one another (Figure 2 ) and are almost parallel, being inclined 11” to each other. The distance between vicinal nonbonded pyridyl carbon atoms varies from an extraordinary close 2.S1 A between Czof one pyridine and of the second pyridine, to a more normal 3.34 at CG-CG’.

J . Org. Chem., Vol. 36, No. 20,1971 2993

OVERCROWDED MOLECULES.I1

f

Under such steric constraint, it seems reasonable that the pyridines would suffer restricted rotation, making possible two diastereoisomers other than that known from the X-ray study. The three isomers would differ solely in the orientation of the pyridines with respect to one another as indicated for 11, 11-1 and 11-11. However, we have no experimental evidence

I

I

OAc

I

I

H

HoR

8Y 00

Wavelength (mp)

11-11

suggesting the presence of the latter two possibilities. Each of 1la-e appeared homogeneous based on melting point behavior and tlc analysis. More significant is the fact that the position of the hydroxyl proton signals in their nmr spectrum (CDCL) was concentration independent, located as a two-proton broadened singlet a t a low-field position (-12.5 ppm). This result is only consistent for the energetically preferred, intramolecularly hydrogen-bonded isomer 11. Spectral Properties.--Some effects of overcrowding on the spectral properties of 11 are easily recognized through a comparison of uv and mass spectral data of lla with like data obtained for the lesser strained isomeric phenanthrenediols 13 and 15. Perturbations resulting from distortion of the phenanthrene nucleus are known to produce bathochromic and hyperchromic shifts of the longer wavelength abs o r p t i o n ~ and , ~ such shifts are apparent in comparison with the uv spectra of the diacetyl derivatives of l l a , 13, 15, and the parent 3,6-dihydroxyphenanthrene (Figure 3). S x t r a of the diacetates rather than the parent diols are compared to eliminate unknown contributions resulting from hydroxyl-pyridine hydrogen bonding. The mass spectral fragmentation of l l a also shows abnormalities attributable to overcrowding. The initial and major fragmentation of l l a involves loss of a pyridyl group, a fragmentation of minor importance in the lesser strained 13 and 15 (Table I). This mode of TABLE I IMPORTANT ]IONS I N THE M A S S SPECTRA O F m/e

Assignment

364 363 286

ivI - 1 1M - PIT

IM

-.----Re1 lla

21 .o 0.6 100.0

l l a , 13, AND 15

intensity, ’%----13

65.0 100.0

1.7

15

100.0 96.0 8.6

(9) For example, see G . M. Badger, J. E. Campbell, J. W. Cook, R. A. Raphael, and A. I. Scott, J . Chem. Soc., 2326 (1950); H. H. Jaff4 and M. Orchin, “Theory and Applications of Ultraviolet Spectroscopy,” Wiley, New York, N . Y., 1962, pp 384-449.

Figure 3.-Ultraviolet spectra of the diacetyl derivatives of 1 la, 13, 15, and phenanthrene-3,6-dioI.

cleavage appears to be characteristic of these 4,j-dipyridylphenanthrene derivatives and has proved valuable in structure elucidation of reaction products derived from free radical oxidation processes which will be reported at a later time. The nmr data are contained in Table 11. The individual absorptions in the spectrum of l l e were unT S B L E 11 NMRCHEMICAL SHIFTS”O F

~,~-BIS(~-PYRIDYL)PHENANTHREKEE-~,~-DIOLS

Compd

Rz

Hp

H,

Hs

HI

RI

He

OH

7.24 7.77 7.54 6.83 7.39 6.97 8.03 12.5 llb 8.06 7.48 6.85 7.47 7.04 8.04b llc 2.42 7.63 7.49 6.84 7.39 6.96 8.01 13.0 l l d 7.18 7.74 7.52 6.72 7.22 2.26 7.84 12.5 l l e 2.29 7.59 7.46 6.74 7.20 2.23 7.82 12.6 6 values in ppm downfield from internal TMS. Obtained with a Varian HA-100 spectrometer using 1-4y0 solutions in CDC13. Accuracy &0.01 ppm. b Partially obscured by Hg. lla

ambiguously assignable since the positions of the methyl substituents were unequivocal from the synthesis, and the “apparent” coupling constants in this and the other 11z 8-9 Hz, lJh5[ ‘v 7.5 Hz, and IJ46( N compounds (lJ34/ 2 Ha) defined the positions of the protons with respect to one another. Using these assignments, absorptions of the remaining compounds could be readily identified, since the chemical shifts mere such that no serious second-order perturbations appeared to be present.

2994 J . Org. Chem., Vol. 36, No. $0, 1971

FIELDS AND REGAN TABLE I11

PYRIDYL-SUBSTITUTED 2-NAPHTHOLS AND

uv,

Yield, Compd

%

MP, OC

5a” 5ba 5ca 5db

91 95 87 93

98-100

x:yN

(log e)

232 (4.67) 250 (4.38) 318 (3.98) 351 (3.90) 7b 86 194-195 259 (4.69), 315 (4.00) 353 (3.50), 367 (3.48) 9b 88 126-127 226 (4.59), 246 sh (4.44) 281 (4.31), 361 (3.49) 383 (3.46) Recrystallized from methylcyclohexane. a Reference 4.

PHENANTHROLS

%----

c-Calcd,

%-

C

H

N

.-----Found, C

H

N

60.1

3.3

4.7

59.8

3.1

4.6

84.1

4.8

5.2

84.5

5.0

5.2

84.1

4.8

5.2

84.2

4.9

5.1

TABLE IV DIPYRIDYL-SUBSTITUTED PHENANTHRENEDIOLS --Calcd,

llaasb

88

1lbc llcd

86

1Id lle 13a,e 15”J

d

70 92

221-223

239 (4.66), 295 (4.49), 312 sh (4.40) 402 (3.60), 420 (3.63)

290 dec 274-277 ($th dec) 231-233 267-269 (with dec) 134-135 236-237

%------. N

%-

-Found, C

H

N

7.7

78.8

4.7

7.7

5.4

55.1 78.9

2.8 5.4

5.2 7.2

79.4 79.6

5.0 5.7

7.2 6.7

C

H

79.1

4.4

55.2 78.7

2.7 5.2

7.1

79.6 80.0

5.1 5.7

6.7

7.1

239 (4.59), 321 (4.39), 390 sh (3.45) 79.1 4.4 7.7 78.8 4.5 7.6 241 (4.46), 273 (4.62), 310 (4.35), 79.1 4.4 7.7 78.7 4.8 7.9 380 (3.73) 5 Recrystallized from methylcyclohexane. Diacetyl derivative, mp 237-241 ’. Recrystallized from CHzClz-ligroin (bp 30-60’). Solvated: 0.25H20. Recrystallized from ethanol-HzO. Diacetyl derivative] mp 176-179‘. f Diacetyl derivative, mp 254-256’.

rudimentary starting materials. 2,5-Lutidine was converted by known proceduresI6 to 5-methyl-2-( 1,3-dioxolan-2-yl)pyridine [bp 55’ (110 mm), TPD 1.52151, which was further characterized as its methoperchlorate, mp 107-109’. Anal. Calcd for C ~ O H I & ~ N OC, ~ : 42.8; H, 5.0; N, 5.0. Found: C,42.8; H , 5.4; N , 5.3. This pyridine acetal was then employed in the Bradsher diazoniapentaphene synthesisll to give 3,10-dimethyl-4a$a-diazoniapentaphene diperchlorate: uv max (CHaCN) 217 nm (log e 4.69), 253 (4.02), 256 sh (4.01), 286 (4.24), 298 (4.32), 340 (4.51), 353 (4.56), 364 (4.38), 384 (4.51), 418 (3.66), 444 (3.61). Experimental Section1‘ Its reaction with excess 1,l-diethoxyethylenexe and 1,l-diethoxypropene14afforded 10d and 10el respectively, as amorphous Azoniapolycyclic Ketene Acetal Adducts.-Adducts la-d, 6 , white solids. Adducts lob-e were not fully characterized other 8, and 10a have been described previously.6 The following new than to establish in each case the absence of absorbances longer adducts were prepared by the same general procedure. In each than 270 nm in their uv spectra. case the nmr spectrum was consistent with the assigned strucAdduct 12, mp 217’ (with dec), and adduct 14, mp 270’ dec, ture. were obtained &s crystalline solids from bis cycloadditions of 1,lAdducts 10b and 1Oc were isolated as amorphous white powders diethoxyethylene with 4a, 12a- and 12a,l4a-diazoniapentaphene in quantitative yields following treatment of 4a,8a-diazoniapentaphene diperchlorate12 with I-brom0-2,2-diethoxyethylene~~ perchlorates,I2 respectively. Anal. Calcd for Ca~Ha&l~N2012:C, 53.8; H, 5.3; N, 3.9. and with l,l-dietho~ypropene,~4 respectively. Found (for 12): C, 53.4; H, 5.3; N, 4.0. Found (for 14): The synthesis of 10d and of 10e necessitated beginning with C,53.6; H,5.3; N,3.9. Naahthol-Phenanthrol Svnthesk-The following procedure for &e preparation of 4,~-bis(2-pyridyl)phenanth~e~e-3,6-diol (10) P . I. Rose, unpublished results. ( l l a ) is typical of that used in the syntheses of the products listed (11) Melting points (uncorrected) mere determined on a Thomas-Hoover in Tables I11 and IV. apparatus. Ultraviolet absorption spectra were recorded b y a C a w Model A solution of loa6 (23.9 g, 0.032 mol) in 100 ml of 6 iV hydro14 recording spectrophotometer. Infrared spectra were obtained with a chloric acid was heated under reflux for 1 hr and then concentrated Perkin-Elmer Infracord spectrometer. P\-mr spectra were determined on a rotary evaporator t o a viscous syrup. A mixture of this a t ambient probe temperature n i t h either a Varian A-60 or HA-100 specsyrup, 10 g of anhydrous sodium acetate, and 200 ml of acetic trometer. Peak positions are reported in parts per million downfield from

The nmr data combined with the nonbonded internuclear distances from the X-ray data provide an unusual opportunity to test the widely used “ring current” model for diamagnetic anistropy of aromatic compounds. This material is discussed in detail in another report.1° The results show good agreement between the experimentally observed shifts and those calculated from theory.

internal tetramethylsilane. I n a few cases CHCls was used as a secondary reference. The mass spectra were determined on a Consohdated 21-110 instrument operating a t nominal resolution. (12) C.K.Bradsher and J. C. Parham, J . Org. Chem., 2B, 856 (1964). (13) F. Reyersted and 8. M. McElvain, J . Amer. Chem. Soc., 72, 1661 (1980). (14) S.M. McElvain and W.R . Davie, %bid.,73, 1400 (1951).

(15) V. Boekelheide and W. J. Linn, ibid., 76, 1286 (1954); C. K. Bradsher and J. C. Parham, J . Org. Chem., 28, 83 (1963). (16) S. M.McElvain, “Organio Syntheses,” Collect. Vol. 111, Wiley, New York, N.Y., 1055,p 506.

J. Org. Chem., Vol. 36, No. 20,I971 2995

OVERCROWDED MOLECULES.I11 anhydride was refluxed for 1 hr. The residue obtained upon concentrating the reaction mixture was triturated in 250 ml of 5% sodium bicarbonate solution, giving 14.3 g of the diacetyl derivative of 1la, as light tan crystals. An analytical sample had mp 237-241' after two recrystallizations from methylcyclohexane; uv, Figure 3; nmr 6 1.88 (s, 6 H, COCH3), 6.35 (d of m, 2, two pyridine H ) , 6.90-8.20 (m, 12, Ha, Hp, H,, and remaining pyridine H with H, appearing as a singlet a t 7.80; Hp, d, J = 9 Hz a t 7.98; H a , d, J = 9 Hz at 7.30); mass spectrum (70 eY) m/e 448 ( A I + ) , 406, 370, 364, 328,286. Anal. Calcd for CzsHtoN2Ol: C, 75.0; H, 4.5; N, 6.2. Found: C , 75.0; H, 4.9; N,6.3. The above product was deacetylated by heating a solution of it in 100 ml of 6 N hydrochloric acid for 0.5 hr a t reflux temperature. The resulting crystalline dihydrochloride was isolated after concentrating the reaction mixture to dryness; its neutralization with 5% sodium bicarbonate solution gave 10.2 g (88%) of essentially pure (tlc) l l a as fine yellow needles.

Registry No.-Sd, 30309-81-0; 7, 30309-82-1; 9, 30309-83-2; l l a , 26244-86-0; l l a diacetyl derivative, 26244-85-9; 1 Ib, 30309-86-5; 1 IC, 30309-87-6; 1 Id, 30309-88-7 ; l l e , 30309-89-8; 12, 30259-90-6; 13 diacetyl derivative, 30309-90-1 ; 14, 30259-91-7; 15 diacetyl derivative, 30309-91-2; 3,6-diacetylphenanthrene, 30309-92-3; 5-methyl-2-( 1,3-dioxolan-2-yl)pyridine, 30309-93-4, 30309-94-5 (methoperchlorate) ; 3,lO-dimethyl-4a,8a-diaxoniapentaphenediperchlorate, 30309-95-6. Acknowledgment.-We wish to thank Mr. D. P. Maier for supplying the mass spectral data and Dr. P. I. Rose for technical assistance in recording some of the nmr spectra and for helpful discussions regarding their interpretation.

Overcrowded Molecules. 111. 13,14-Bis(2-pyridyl)pentaphene and Related Compounds D. L. FIELDS,* T. H. REGAN,AND R. E. GRAVES Research Laboratories, Eastman Kodak Company, Rochester, New York

14660

Received January 6 , 1971 The reaction of benzync with 4a-azoniaanthracene and 4rt18a- and 4a112a-diazoniapentaphenesalts produces, in good yields, azoniatriptycene-type adducts, which are thermolyzed in boiling acetic anhydride to 9-(2-pyridyl)anthracene ( 5 ) , 5,13- (15), and 13,14-bis(Z-pyridyl)pentaphenes(l8), respectively. The nmr spectrum of 19, the bis-A7-methylquaternary salt of 15, displays each of its N-methyl resonances as two sharp peaks of equal intensity up to 130°, indicative that both pyridine rings are suffering restricted rotation giving rise to a pair of geometric isomers. The nmr spectrum of the mono-N-methyl quaternary salt of 18 shows the presence of a t least two of the four possible geometrical isomers; these, however, begin to interconvert at room temperature and are equilibrated above 80" (AP ,- 17 kcal/mol). The bis-N-methyl quaternary salt of 18 shows its N-methyl absorptions as two singlets (2: 1 area ratio) a t 70". The major peak is temperature independent, whereas the minor peak broadens as the temperature is lowered, finally separating into two singlets of equal area at 20". These results are interpreted in terms of an unexpectedly facile pentaphene ring inversion accompanied by a synchronous rotation of both pyridines.

*

Previously it has been shown that, in marked contrast to the low order of reactivity that azonia polycyclic aromatic compounds display toward conventional electrophilic dienophiles, a variety of these compounds 2 cycloaddiwill readily undergo stereoselective 4 tions with nucleophilic olefins including enamines and ketene acetaJs to give adducts in high yields.' The ketene diethyl acetal adduct of 5-acetoxy-8-tert-butyl4a-azoniaanthracene perchlorate and the bis adduct of 4a,8a-diazoniapentaphenediperchlorate have been particularly useful, serving as precursors to the interesting, highly overcrowded naphthalene 1 and phenanthrene 2,a respectively, via the synthesis shown in Scheme I. Benzyne is considered to be an electrophilic reagent. Nevertheless, we have now found that it too will undergo cycloaddition efficiently with azonia polycyclics to afford a,zoniatriptycene-type adducts (4). Our interest in these types of compounds has been twofold. First, they serve as precursors to substituted anthracenes and related hydrocarbons in a synthesis to be described in a separate publication. Second, and relevant to this paper, is the discovery that their thermolysis usually leads to pyridyl-substituted polycyclic aromatic hydrocarbons, the simplest of these

+

(1) D. L. Fields, T. H. Regan, and J. C. Dignan, J. Org. Chem., 33, 390 (1968). (2) D. L. Fields and T. H. Regan, ibid.,36, 2986 (1971). (3) D. L. Fields and T. H. Regan, ibid.,S6, 2991 (1971).

being 9-(2-pyridyl)anthracene ( 5 ) . Exploitation of this reaction sequence as a new synthetic approach to overcrowded molecules has been profitably investigated

c10,-

3

4

Q

m 5

in the synthesis of highly strained nonplanar, and therefore chiral, 13,14-bis(2-pyridyl)pentaphene. Manifestations of the ring strain and unusual geometry associated with this compound parallel those previously observed with 4,s-dipyridylphenanthrene2 in several ways. One interesting and distinctive difference is discussed, related to conformational isomerism.